Agricultural baler with variable speed plunger

ABSTRACT

An agricultural harvesting machine for crop material including a crank arm connected to a rotational power source, a plunger having an extended position which is located further rearward in a compression chamber than a retracted position, and a connecting link connected between the plunger and the crank arm. One of the connecting link and the crank arm has a variable length. The plunger moves between the retracted and extended positions during a run mode as the crank arm rotates. The plunger changes speeds during an event phase based upon one of the connecting link and the crank arm varying lengths.

CROSS-REFERENCE TO RELATED APPLICATIONS

N/A

FIELD OF THE DISCLOSURE

The present disclosure relates to agricultural harvesting machines having a plunger for compressing crop material into a crop package.

BACKGROUND

Agricultural balers gather, compress, and shape crop material into a bale. There are different types of balers which create rectangular or square bales or cylindrical or round bales. Bales can be bound with netting, strapping, wire, or twine. A baler that produces small rectangular bales is often referred to as a square baler. Another type of baler is one that produces large rectangular bales, often referred to as large square baler.

Large square balers have been used in crop harvesting for many years. One advantage over other types of balers is that they densify the crop into large rectangular shaped bales, which can minimize shipping and storage costs. Large square balers usually utilize a compression system including a gearbox with a fixed length crank arm and a fixed length connecting rod which is attached to a plunger. During each rotation of the crank arm, the plunger compresses the crop in a baling chamber by extruding the crop though a rectangular chute as the plunger moves towards the rear of the baler. Crop is usually metered from a pre-compression chamber into the baler chamber. One purpose for having a pre-compression chamber is to collect enough crop material to make a full flake of hay prior to moving the crop in front of the plunger to be compressed.

One of the problems with balers having a fixed length connecting rod is that the plunger movement and speed cannot be varied relative to the crank arm speed. For a given crank arm speed, the plunger compresses the crop at the same speed for each stroke, and the dwell time of the plunger at the extended position is also the same for each stroke.

SUMMARY

This summary is provided to introduce a selection of concepts that are further described below in the detailed description and accompanying drawings. This summary is not intended to identify key or essential features of the appended claims, nor is it intended to be used as an aid in determining the scope of the appended claims.

The present disclosure includes a system which allows the movement of the plunger to be controlled independently of the movement of the crank arm.

According to an aspect of the present disclosure, an agricultural harvesting machine for crop material may include a crank arm connected to a rotational power source, a plunger having an extended position which is located further rearward in a compression chamber than a retracted position, and a connecting link connected between the plunger and the crank arm. One of the connecting link and the crank arm may have a variable length. The plunger can move between the retracted and extended positions during a run mode as the crank arm rotates. The plunger can change speeds during an event phase based upon one of the connecting link and the crank arm varying lengths.

During the event phase, one of the connecting link and the crank arm can lengthen and shorten to a plurality of different lengths to change the speed of the plunger at a different rate than caused by the rotation of the crank arm.

The agricultural harvesting machine may further include a controller configured to change the speed of the plunger.

The agricultural harvesting machine may further include a controller configured to vary the length of one or more of the connecting link and the crank arm.

According to an aspect of the present disclosure, a method of varying the speed of a plunger in an agricultural harvesting machine may include one or more of the following steps: extending and retracting a plunger into and out of a compression chamber as a crank arm rotates to compress crop material based upon sensing a run mode of the agricultural harvesting machine; and varying the speed of the plunger by lengthening and shortening one of the crank arm and a connecting link positioned between the crank arm and the plunger based upon sensing an event phase of the agricultural harvesting machine.

During the event phase, the lengthening and shortening of one of the connecting link and the crank arm can change the speed of the plunger at a different rate than caused by the rotation of the crank arm.

These and other features will become apparent from the following detailed description and accompanying drawings, wherein various features are shown and described by way of illustration. The present disclosure is capable of other and different configurations and its several details are capable of modification in various other respects, all without departing from the scope of the present disclosure. Accordingly, the detailed description and accompanying drawings are to be regarded as illustrative in nature and not as restrictive or limiting.

BRIEF DESCRIPTION OF THE DRAWINGS

The detailed description of the drawings refers to the accompanying figures in which:

FIG. 1 is a perspective view of an agricultural harvesting machine coupled to an agricultural vehicle;

FIG. 2 is a front perspective view of an agricultural harvesting machine, according to one embodiment;

FIG. 3 is a schematic side view an agricultural harvesting machine, according to one embodiment;

FIG. 4 is a side view of a portion of an agricultural harvesting machine, according to one embodiment;

FIG. 5 is a perspective view of a portion of an agricultural harvesting machine, according to one embodiment;

FIG. 6 is a side view of a portion of an agricultural harvesting machine, according to one embodiment;

FIG. 6A is a side view of a portion of an agricultural harvesting machine, according to one embodiment;

FIG. 7 is a schematic side view of an agricultural harvesting machine, according to one embodiment;

FIG. 8 is a schematic side view of an agricultural harvesting machine, according to one embodiment;

FIG. 9 is a schematic side view of an agricultural harvesting machine, according to one embodiment;

FIGS. 10A, 10B, 10C, and 10D are schematic side views of an agricultural harvesting machine, according to one embodiment;

FIGS. 11A and 11B are schematic side views of an agricultural harvesting machine, according to one embodiment;

FIGS. 12A, 12B, and 12C are schematic side views of an agricultural harvesting machine, according to one embodiment;

FIGS. 13A, 13B, 13C, and 13D are schematic side views of an agricultural harvesting machine, according to one embodiment;

FIGS. 14A, 14B, 14C, and 14D are schematic side views of an agricultural harvesting machine, according to one embodiment;

FIGS. 15A, 15B, 15C, and 15D are schematic side views of an agricultural harvesting machine, according to one embodiment;

FIG. 16 is a schematic diagram of an agricultural harvesting machine, according to one embodiment;

FIG. 17 is a schematic diagram of an agricultural harvesting machine, according to one embodiment;

FIG. 18 is a flow chart for a method of operating a variable speed plunger in an agricultural harvesting machine, according to one embodiment; and

FIG. 19 is a flow chart for a method of operating a variable speed plunger in an agricultural harvesting machine, according to one embodiment.

Like reference numerals are used to indicate like elements throughout the several figures.

DETAILED DESCRIPTION

The embodiments disclosed in the above drawings and the following detailed description are not intended to be exhaustive or to limit the disclosure to these embodiments. Rather, there are several variations and modifications which may be made without departing from the scope of the present disclosure.

FIG. 1 illustrates an agricultural harvesting machine 100, such as a baler, according to one embodiment. Although a large square baler is shown, this disclosure also applies to other balers and harvesting machines. The agricultural harvesting machine 100 may be coupled to an agricultural vehicle 101, such as a tractor, or the agricultural harvesting machine 100 may be self-propelled. The agricultural harvesting machine 100 may be combined or integrated with a cotton harvester, a combine, or other harvesting machines. The agricultural harvesting machine 100 and the agricultural vehicle 101 may each include a controller 180, which will be discussed in more detail below. For ease of reference, the remaining description will refer to the agricultural harvesting machine 100 as a baler. As depicted in FIG. 1, the baler 100 may move across a field and gather and process crop material to form a crop package 118, such as a bale. The baler 100 may then eject the bale 118 from the rear of the baler 100.

With reference to FIGS. 1-3 and 5, the baler 100 may include a frame 102, ground engaging devices 104, such as wheels, a hitch 106 for attachment to a tractor or other vehicle, and an input shaft 108, such as a power-take-off (PTO) shaft, which can receive rotational power from a tractor 101, other agricultural vehicles, or other power sources. As depicted in the FIGURES, for example in FIG. 3, the forward portion or direction of the baler 100 is generally to the left and the rearward portion or direction of the baler 100 is generally to the right. The baler 100 may include a pick-up mechanism 110 which gathers crop material from the ground surface and feeds it into the baler 100. The pick-up mechanism 110 may include various pick-up apparatus 111 including, but not limited to, tines, forks, augers, conveyors, baffles, a cutter or pre-cutter assembly, or any combination of the preceding. The baler 100 may include a housing 116, which generally shields various internal components of the baler 100. The input shaft or PTO shaft 108 may connect to an input of the gear train or transmission 112 providing rotational power to the baler 100 from the tractor 101 or other associated vehicle or power source. The transmission 112 may include a gearbox which converts the rotational motion of the input shaft 108 along a generally longitudinal axis of the baler 100 to a rotational motion along a generally transverse axis of the baler 100. A flywheel 114 may connect to the input shaft 108, the transmission 112, or both. The flywheel 114 can be positioned between the transmission 112 and the input shaft 108, as shown.

The baler 100 can have a startup mode or state in which the input shaft 108 receives rotational power and begins to move or rotate, which causes the transmission 112, flywheel 114, and other components to also begin to move or rotate. The baler 100 remains in the startup mode until these components accelerate to a pre-determined or operational speed required for normal function of the baler 100. Once these components have reached the operational speed, then the baler 100 can proceed from the startup mode to an operational mode or state. One or more of the components of the baler 100 can be decoupled from the input shaft 108, or rotational power source, during the startup mode.

With references to FIGS. 2-4 and 7-9, the baler 100 may include a pre-compression chamber 120 which receives crop material from the pick-up mechanism 110 and accumulates the crop material until a pre-determined fill condition. A loading mechanism 122, or stuffer, moves crop material into the pre-compression chamber 120. The loading mechanism 122 may include projections 124, such as tines or forks, which are inserted or extended into the pre-compression chamber 120, at or near the entrance, to move crop material into and through the pre-compression chamber 120. The projections 124 can then be removed or retracted from the pre-compression chamber 120, at or near the exit, and repositioned at or near the entrance of the pre-compression chamber 120.

The pre-compression chamber 120 may include an accumulation phase and a loading phase. During the accumulation phase, the loading mechanism 122 moves crop material provided by the pick-up mechanism 110 into the pre-compression chamber 120 until the pre-compression chamber 120 reaches a pre-determined fill condition, as shown for example in FIG. 7. The projections 124 may move from at or near the entrance of the pre-compression chamber 120 to an intermediate position in the pre-compression chamber 120 in a smaller accumulation stroke pattern 126. In this manner, the loading mechanism 122 adds or accumulates crop material in the pre-compression chamber 120 until the pre-determined fill condition has been attained. The loading phase may then be initiated. During the loading phase, the loading mechanism 122 moves crop material from the pre-compression chamber 120 into the compression chamber 140, as shown for example in FIG. 8. The projections 124 may move from at or near the entrance of the pre-compression chamber 120 to at or near the exit of the pre-compression chamber 120 in a larger loading stroke pattern 128.

A trip mechanism 130 may determine when the pre-determined fill condition of the pre-compression chamber 120 has been attained. The trip mechanism 130 may include mechanical devices, sensors, or both. The trip mechanism 130 may include one or more trip plates 132 movably positioned at least partially within the pre-compression chamber 120. The trip plate 132 may move in response to crop material filling the pre-compression chamber 120 until the pre-determined fill condition is attained. A sensor 134 may determine the position of the trip plate 132. Alternatively, or additionally, the trip mechanism 130 may include one or more sensors 136 positioned at any location to sense the fill condition within the pre-compression chamber 120. The sensor 136 could be positioned on one or more of the top, bottom, and side walls of the pre-compression chamber 120. The sensor 136 could be positioned on the loading mechanism 122 including, but not limited to, on the projection 124. The sensor 136 can detect or sense at least one of load, force, displacement, rotation, density, and pressure corresponding to the fill condition of the pre-compression chamber 120.

With reference to FIGS. 3, 5, and 7-9, the baler 100 may include a crank arm 142 connected to the rotational output of the transmission 112. The baler 100 may include a connecting link 144 connected between the crank arm 142 and a plunger 146. The connecting link 144 may include one or more members connecting the crank arm 142 to the plunger 146. The crank arm 142 rotates based upon the output of the transmission 112 and the plunger 146 moves in a reciprocal motion as the crank arm 142 rotates. A sensor 143 may detect or sense the rotational speed, position, or both of the crank arm 142. The plunger 146 extends into the compression chamber 140 compressing the crop material, as shown for example in FIG. 9, and then at least partially retracts from the compression chamber 140 to allow more crop material to enter the compression chamber 140, as shown for example in FIG. 8. A sensor 147 can detect or sense one or more of the position, direction, and speed of the plunger 146. The connecting link 144 can have extended and retracted conditions or positions. The connecting link 144 can extend or lengthen and retract or shorten, as shown for example in FIGS. 10A-D. The connecting link 144 can also have a plurality of intermediate positions between a fully extended position and a fully retracted position. The connecting link 144 can be a hydraulic or pneumatic actuator or cylinder, a linear actuator, or other types of actuators. The connecting link 144 can be a double acting cylinder.

Alternatively or additionally, the crank arm 142 can extend or lengthen and retract or shorten, as shown for example in FIGS. 13A-D. The crank arm 142 can have extended and retracted conditions or positions. The crank arm 142 can also have a plurality of intermediate positions between a fully extended position and a fully retracted position. The crank arm 142 can be a hydraulic or pneumatic actuator or cylinder, a linear actuator, or other types of actuators. The crank arm 142 can be a double acting cylinder. In one or more embodiments, both the connecting link 144 and the crank arm 142 can have extended and retracted conditions or positions. The baler 100 may include a plunger brake 148 to maintain the plunger 146 at a pre-determined position. When engaged, the plunger brake 148 may maintain the plunger 146 in a substantially stationary position, in which the plunger 146 moves slightly or is completely stationary. The plunger brake 148 may prevent or reduce the movement of the plunger 146 in a retracted condition or position. The plunger brake 148 may operate mechanically, hydraulically, pneumatically, electrically, or any combination of the preceding.

With reference to FIGS. 2-3, 6, and 6A, the baler 100 may include a binding or knotter system 150, which binds the compressed crop material in the compression chamber 140 into a crop package, such as a bundle or bale. The binding system 150 may include one or more binding or knotter assemblies 152 and one or more binding material needles 154, which can deliver binding material to the binding assemblies 152. The binding system 150 wraps and secures a binding material around the compressed crop material during a binding operation. A sensor 151 may detect or sense when the binding system 150 is activated and the binding operation is commenced. The baler 100 may include a measuring device 156, such as a star wheel, which measures the length of the compressed crop material within the compression chamber 140. The measuring device 156 can activate the binding system 150 when the compressed crop material within the compression chamber 140 reaches a desired mass, size, or length. The measuring device 156 may activate the binding assembly 152 via a mechanical trip assembly 158. The one or more binding material needles 154 may each move from a lowered position generally below or underneath the baler 100, shown for example in FIG. 6, to a raised position, as shown for example in FIG. 6A, passing through a slot in the bottom of the compression chamber 140, a vertically extending slot 149 in the plunger 146, and a slot in the top in of the compression chamber 140. The one or more needles 154 may deliver binding material, such as string or twine, to the binding assembly 152, which secures the binding material around the compressed crop material within the compression chamber 140. A sensor 157 may detect or sense when the measuring device 156 activates the mechanical trip assembly 158, or when the mechanical trip assembly 158 activates the binding assembly 152, or both. Alternatively or additionally, a sensor 157 may measure the rotation of the measuring device 156 and then activate the binding system 150 at a pre-determined amount of rotation using an electrical or electronic trip assembly instead of the mechanical trip assembly 158.

FIGS. 10A-D illustrate a plunger 146 in an active or run mode or state, according to one embodiment. In the active or run mode, the plunger 146 extends and retracts in a reciprocal motion along an axis Z as the crank arm 142 progresses around a full revolution. The plunger 146 can complete a full stroke when it moves from the fully retracted position to the fully extended position and then back again as the crank arm 142 completes one revolution. As depicted in the embodiment in FIGS. 10A-D, the crank arm 142 has a fixed length and the connecting link 144 has a variable or adjustable length. The connecting link 144 is pivotally coupled to the crank 142 at or near one end and to the plunger 146 at or near the other end.

FIG. 10A illustrates the plunger 146 in a fully retracted position or condition with the crank arm 142 in an initial or forward position approximately parallel to the direction of travel of the plunger 146 in a direction away from the plunger 146 and the compression chamber 140. In this position, the connecting link 144 can be retracted to or near its shortest or minimum length.

FIG. 10B illustrates the plunger 146 in an intermediate position or condition as the plunger 146 travels towards the compression chamber 140. The crank arm 142 is positioned approximately perpendicular to the direction of travel of the plunger 146. The connecting link 144 is extended to an intermediate length between fully retracted and fully extended.

FIG. 10C illustrates the plunger 146 in a fully extended position or condition with the crank arm 142 in a rearward position approximately parallel to the direction of travel of the plunger 146 in a direction towards the plunger 146 and the compression chamber 140. In this position, the connecting link 144 can be extended to or near its longest or maximum length. The dimension X represents the total amount of travel of the pivotal connection between the crank arm 142 and the connecting link 144 along the axis Z, and dimension Y represents the corresponding total amount of travel of the plunger 146 along the axis Z. As depicted, the dimension Y is greater than dimension X due to the extension and retraction of the connecting link 144.

FIG. 10D illustrates the plunger 146 in an intermediate position or condition as the plunger 146 travels away from the compression chamber 140. The crank arm 142 is positioned approximately perpendicular to the direction of travel of the plunger 146. The connecting link 144 is retracted to an intermediate length between fully retracted and fully extended.

FIGS. 11A-B illustrate a plunger 146 in a run mode or state, according to one embodiment. The plunger 146 extends and retracts in a reciprocal motion along an axis Z as the crank arm 142 progresses around a full revolution. As depicted in the embodiment in FIGS. 11A-B, the crank arm 142 has a fixed length and the connecting link 144 has a variable or adjustable length. The connecting link 144 includes a first member 144 a pivotally coupled to the crank 142 and a second member 144 b pivotally coupled to the first member 144 a and the plunger 146. The connecting link 144 includes an actuator 145 pivotally coupled to the first and second members 144 a, 144 b. When the actuator 145 is retracted, the connecting link 144 is retracted, and when the actuator is extended, the connecting link 144 is extended.

FIG. 11A illustrates the plunger 146 in a fully retracted position or condition with the crank arm 142 positioned approximately parallel to the direction of travel of the plunger 146 in a direction away from the plunger 146. In this position, the connecting link 144 can be retracted to or near its shortest or minimum length with the actuator 145 being retracted.

FIG. 11B illustrates the plunger 146 in a fully extended position or condition with the crank arm 142 positioned approximately parallel to the direction of travel of the plunger 146 in a direction towards the plunger 146. In this position, the connecting link 144 can be extended to or near its longest or maximum length with the actuator 145 being extended. The dimension X represents the total amount of travel of the pivotal connection between the crank arm 142 and the connecting link 144 along the axis Z, and dimension Y represents the corresponding total amount of travel of the plunger 146 along the axis Z. As depicted, the dimension Y is greater than dimension X due to the extension and retraction of the connecting link 144.

FIGS. 12A-C illustrate a plunger 146 in a run mode or state, according to one embodiment. The plunger 146 extends and retracts in a reciprocal motion along an axis Z as the crank arm 142 progresses around a full revolution. As depicted in the embodiment in FIGS. 12A-C, the crank arm 142 has a fixed length and the connecting link 144 has a variable or adjustable length. The connecting link 144 includes a first member 144 a pivotally coupled to the crank arm 142 and a second member 144 b pivotally coupled to the first member 144 a and the plunger 146. The connecting link 144 also includes a third member 144 c pivotally coupled to the crank arm 142 and a fourth member 144 d pivotally coupled to the third member 144 c and the plunger 146. The connecting link 144 includes an actuator 145 pivotally coupled to the first and second members 144 a, 144 b at or near one end and the third and fourth members 144 c, 144 d at or near the other end.

FIG. 12A illustrates the plunger 146 in a fully retracted position or condition with the crank arm 142 positioned approximately parallel to the direction of travel of the plunger 146 in a direction away from the plunger 146. In this position, the connecting link 144 can be retracted to or near its shortest or minimum length with the actuator 145 being extended.

FIG. 12B illustrates the plunger 146 in an intermediate position or condition as the plunger 146 travels towards the compression chamber 140. The crank arm 142 is positioned approximately perpendicular to the direction of travel of the plunger 146. The connecting link 144 is extended to an intermediate length between fully retracted and fully extended with the actuator 145 being at least partially extended.

FIG. 12C illustrates the plunger 146 in a fully extended position or condition with the crank arm 142 positioned approximately parallel to the direction of travel of the plunger 146 in a direction towards the plunger 146. In this position, the connecting link 144 can be extended to or near its longest or maximum length with the actuator 145 being retracted. The dimension X represents the total amount of travel of the pivotal connection between the crank arm 142 and the connecting link 144 along the axis Z, and dimension Y represents the corresponding total amount of travel of the plunger 146 along the axis Z. As depicted, the dimension Y is greater than dimension X due to the extension and retraction of the connecting link 144.

FIGS. 13A-D illustrate a plunger 146 in a run mode or state, according to one embodiment. The plunger 146 extends and retracts in a reciprocal motion along an axis Z as the crank arm 142 progresses around a full revolution. As depicted in the embodiment in FIGS. 13A-D, the crank arm 142 has a variable or adjustable length and the connecting link 144 has a fixed length. The connecting link 144 is pivotally coupled to the crank 142 at or near one end and to the plunger 146 at or near the other end.

FIG. 13A illustrates the plunger 146 in a fully retracted position or condition with the crank arm 142 positioned approximately parallel to the direction of travel of the plunger 146 in a direction away from the plunger 146. In this position, the crank arm 142 can be retracted to or near its shortest or minimum length.

FIG. 13B illustrates the plunger 146 in an intermediate position or condition as the plunger 146 travels towards the compression chamber 140. The crank arm 142 is positioned approximately perpendicular to the direction of travel of the plunger 146. The crank arm 142 is extended to an intermediate length between fully retracted and fully extended.

FIG. 13C illustrates the plunger 146 in a fully extended position or condition with the crank arm 142 positioned approximately parallel to the direction of travel of the plunger 146 in a direction towards the plunger 146. In this position, the crank arm 142 can be extended to or near its longest or maximum length. The dimension X represents the total amount of travel of the pivotal connection between the crank arm 142 and the connecting link 144 along the axis Z, and dimension Y represents the corresponding total amount of travel of the plunger 146 along the axis Z. As depicted, the dimension X is substantially the same as dimension Y due to the crank arm 142 extending and retracting instead of the connecting link 144.

FIG. 13D illustrates the plunger 146 in an intermediate position or condition as the plunger 146 travels away from the compression chamber 140. The crank arm 142 is positioned approximately perpendicular to the direction of travel of the plunger 146. The crank arm 142 is retracted to an intermediate length between fully retracted and fully extended.

FIGS. 10A-13D have depicted the connecting link 144 as varying or adjusting in length in the run mode. Alternatively, the crank arm 142 could have a variable or adjustable length or both the crank arm 142 and the connecting link 144 could have variable or adjustable lengths.

FIGS. 14A-D illustrate a plunger 146 in an inactive or decoupled mode or state, according to one embodiment. The plunger 146 can be decoupled from the crank arm 142 when the first and second valves 164, 166 are in their respective dump positions and the pump 160 is in the neutral mode. In the decoupled mode, the plunger 146 can be allowed or permitted to move or float independent of the crank arm. Conversely, the plunger 146 can be coupled to the crank arm 142 when the first and second valves 164, 166 are in their respective operation positions and the pump 160 is in the operation mode alternatively providing fluid to the first and second ports 176, 178 of the connecting link 144 via the first and second valves 164, 166. In the inactive mode, the plunger 146 can be located anywhere along an axis Z between and including the fully retracted and fully extended positions independent of the movement and position of the crank arm 142. The plunger 146 can remain in its position along an axis Z as the crank arm 142 progresses around a full revolution. The plunger 146 may remain substantially stationary in its position along the axis Z. Alternatively, the plunger 146 can be allowed to move through a partial stroke instead of a full stroke or through a full stroke but at a slower speed than when the plunger 146 is in the active mode. This can be accomplished by having an extendable connecting link 144, as shown for example in FIGS. 10A-12C, an extendable crank arm 142, as shown for example in FIGS. 13A-D, or both. As depicted in FIGS. 14A-D, the crank arm 142 has a fixed length and the connecting link 144 has a variable or adjustable length. The plunger 146 can be in the inactive or decoupled mode when the baler 100 is in the startup mode.

FIG. 14A illustrates the plunger 146 in a retracted position with the crank arm 142 in the forward position approximately parallel to the direction of travel of the plunger 146 in a direction away from the plunger 146. The connecting link 144 is at an intermediate length between fully retracted and fully extended.

FIG. 14B illustrates the plunger 146 remaining in the retracted position with the crank arm 142 positioned approximately perpendicular to the direction of travel of the plunger 146. The connecting link 144 is retracting or shortening to maintain the plunger 146 in the retracted position. The connecting link 144 is at an intermediate length between fully retracted and fully extended.

FIG. 14C illustrates the plunger 146 remaining in the retracted position with the crank arm 142 in the rearward position approximately parallel to the direction of travel of the plunger 146 in a direction towards the plunger 146. The connecting link 144 is further retracting or shortening to maintain the plunger 146 in the retracted position. In this position, the connecting link 144 can be at its shortest or minimum length. The dimension X represents the total amount of travel of the pivotal connection between the crank arm 142 and the connecting link 144 along the axis Z while the plunger 146 remains substantially stationary along the axis Z.

FIG. 14D illustrates the plunger 146 remaining in the retracted position with the crank arm 142 is positioned approximately perpendicular to the direction of travel of the plunger 146. The connecting link 144 is extending or lengthening to maintain the plunger 146 in the retracted position. The connecting link 144 is at an intermediate length between fully retracted and fully extended.

FIGS. 15A-D illustrate a plunger 146 in an active or run mode or state, according to one embodiment. The speed of the plunger 146 can vary due to the selectively adjustable length of the connecting link 144 or the crank arm 142. The plunger 146 may increase or decrease speed at any position along the axis Z. The run mode may include an event phase, in which the plunger 146 changes speeds or remains in a pre-determined position for a prolonged or lengthened amount of time due to the change in length of the connecting link 144 or the crank arm 142 as the crank arm 142 continues rotating. The crank arm 142 may rotate through a partial or full revolution causing the connection point between the crank arm 142 and the connecting link 144 to move a specified distance along the axis Z. The change in length of the connecting link 144 or the crank arm 142 can cause the plunger 146 to move at an increased speed and greater distance along the axis Z, or at a decreased speed and lesser distance along the axis Z. The event phase can occur based upon a position of the crank arm 142, connecting link 144, or plunger 146, or it can occur based upon an event, for example the commencement of the binding operation. The event phase can occur during every revolution of the crank arm 142, at a specified or pre-determined number of revolutions of the crank arm 142, or other operations of the baler 100.

As depicted in FIGS. 15A-D, the plunger 146 can move at a first speed from the position shown in FIG. 15A to the position shown in FIG. 15B. The plunger 146 can then continue moving at the first speed from the position shown in FIG. 15B and then begin to slow down as the plunger 146 approaches the position shown in FIG. 15C. The plunger 146 can extend further into the compression chamber 140 as the crank arm 142 moves from the position shown in FIG. 15C towards the position shown in FIG. 15D. This allows for a longer, slower compression of the crop material in the compression chamber 140. The plunger 146 can then move at a faster second speed from the position in FIG. 15D to the position in FIG. 15A to return to the retracted position and reset for the next compression cycle.

Alternately or additionally, the plunger 146 may remain in a pre-determined position as the crank arm 142 continues to rotate. The pre-determined position can be any position between and including fully retracted and fully extended. As shown for example in FIG. 15D, the plunger 146 may remain in the extended, or fully extended, position for a prolonged or lengthened amount of time as the crank arm 142 continues rotating. As depicted in the embodiment in FIGS. 15A-D, the crank arm 142 has a fixed length and the connecting link 144 has a variable or adjustable length. The connecting link 144 is pivotally coupled to the crank 142 at or near one end and to the plunger 146 at or near the other end. The plunger 146 may include one or more vertically extending slots 149 sized to allow the one or more binding material needles 154 to pass through and deliver binding material to the binding assembly 152.

FIG. 15A illustrates the plunger 146 in a fully retracted position or condition with the crank arm 142 in an initial or retracted position approximately parallel to the direction of travel of the plunger 146 in a direction away from the plunger 146 and the compression chamber 140. In this position, the connecting link 144 is at an intermediate length between fully retracted and fully extended. The binding deliver needles 154 are in the lowered position.

FIG. 15B illustrates the plunger 146 in an intermediate position or condition as the plunger 146 travels towards the compression chamber 140. The crank arm 142 is positioned approximately perpendicular to the direction of travel of the plunger 146. The connecting link 144 can be at the same or similar intermediate length as depicted in FIG. 15A, or the connecting link 144 can be further extended to another intermediate length between fully retracted and fully extended. The binding deliver needles 154 remain in the lowered position.

FIG. 15C illustrates the plunger 146 in a fully extended position or condition with the crank arm 142 in an extended position approximately parallel to the direction of travel of the plunger 146 in a direction towards the plunger 146 and the compression chamber 140. In this position, the connecting link 144 is at an intermediate length and can still be extended further to or near its longest or maximum length. In this position, the plunger 146 is compressing the crop material at or near its maximum compression. In some embodiments, the plunger 146 could extend further into the compression chamber 140 to attain the maximum compression after the crank arm 142 begins to rotate away from the compression chamber 140. This allows for a slower compression of the crop material over a longer period of time. As depicted in this embodiment, an event phase has been activated or triggered. The event phase could begin upon the activation of the binding assembly 152, and the commencement of the binding operation, or upon the position of the crank arm 142 or plunger 146. In this embodiment, the binding assembly 152 has been activated and the binding operation has commenced. The binding material needles 154 have moved to their raised position delivering binding material to the binding assembly 152, which can begin securing the binding material around the compressed crop material.

FIG. 15D illustrates the plunger 146 remaining in the fully extended position or condition based upon the activation of the event phase. As depicted, the crank arm 142 is positioned approximately perpendicular to the direction of travel of the plunger 146. The connecting link 144 is extended to or near its longest or maximum length. The activation of the binding assembly 152 can cause the plunger 146 to slow or stop and remain at or near the fully extended position. In this position, the plunger 146 maintains the crop material at or near its maximum compression while the binding assembly 152 secures the binding material around the compressed crop material. Because the plunger 148 remains at or near the fully extended position for a longer period of time, the binding assembly 152 has additional time to secure the binding material around the compressed crop material. In addition, the binding assembly 152 can secure the compressed crop material into a crop package or bale when the compressed crop material is at or near the maximum compression. This can result in the crop packages or bales having a higher density. In this embodiment, the plunger 146 remains at the fully extended position or condition for about a one-fourth or quarter of a revolution of the crank arm 142. In other embodiments, the plunger 146 can remain at the fully extended position for any partial or full revolution or multiple revolutions of the crank arm 142. Once the event phase is complete, for example the binding operation completes or the position of the crank arm 142 changes, the plunger 146 can return from the extended position, as shown in FIG. 15D, to the retracted position, as shown in FIG. 15A, in the remaining quarter revolution of the crank arm 142, or any other partial or full revolution to synchronize the retracted position of the plunger 146 with the initial or forward position of the crank arm 142. This can be accomplished by retracting, or shortening, the connecting link 144 while the crank arm 142 is returning to the starting position depicted in FIG. 15A.

The positions of the plunger 146 and crank arm 142 can be considered synchronized when the position of the rotating crank arm 142 corresponds to the position of the stationary plunger 146 as if they were coupled. For example, the position of the crank arm 142 is synchronized with the position of the plunger 146 if the plunger 146 is extended and the crank arm 142 is in its rearward position, as shown for example in FIG. 10C, or if the plunger 146 is retracted and the crank arm 142 is in its forward position, as shown for example in FIG. 10A. As another example, the position of the crank arm 142 can be synchronized with the position of the plunger 146 if the plunger 146 is approximately midway between its extended and retracted positions and the crank arm 142 is approximately midway between its forward and rearward positions, as shown for example in FIG. 10B or 10C.

In addition to the embodiments depicted in FIGS. 14A-D and 15A-D, the plunger 146 can also be maintained in a plurality of different positions between the extended and retracted positions during a partial revolution, full revolution, or multiple revolutions of the crank arm 142. The baler 100 can have an event which activates or triggers the plunger 146 to slow down and remain in one of the plurality of positions during the event, or speed up to arrive at one of the plurality of positions during the event. The plunger 146 can be maintained in one of the plurality of positions by one or more of the connecting link 144 and the crank arm 142 having variable or adjustable lengths. Some embodiments may include any of the extendable connecting links 144 depicted in FIGS. 10A-12C used with an extendable crank arm 142 depicted for example in FIGS. 13A-D. Other combinations of connecting links 144 and crank arms 142 are also contemplated and within the scope of this disclosure.

FIG. 16 illustrates a schematic diagram of a baler 100, according to one embodiment. The baler 100 may include one or more of the following sensors. An input shaft sensor 109 may be positioned on or near the input shaft 108 and can be any type of sensor which detects or senses the speed or rotation of the input shaft 108. A trip sensor 134 may be positioned on or near the trip mechanism 130 and can be any type of sensor which detects the movement or rotation of the trip mechanism 130. A pre-compression chamber sensor 136 may be positioned on, in, or near the pre-compression chamber 120 and can be any type of sensor which detects a fill condition of the pre-compression chamber 120. A crank arm sensor 143 may be positioned on or near the crank arm 142 and can be any type of sensor which detects movement or rotation of the crank arm 142. A plunger sensor 147 may be positioned on or near the plunger 146 and can be any type of sensor which detects the position or movement of the plunger 146. A binding sensor 151 may be positioned on or near the binding system 150 and can be any type of sensor which detects when the binding system 150 is activated. A measurement sensor 157 may be positioned on or near the binding system 150 and can be any type of sensor which detects when the crop material within the compression chamber 140 has reached a pre-determined quantity.

With reference to FIG. 17, the baler 100 may include a hydraulic, pneumatic, or electrical system to power and actuate the connecting link 144. The following description is directed to an implementation of an example hydraulic system, which is also applicable to a similarly arranged pneumatic or electrical system. The baler 100 may include a hydraulic pump 160, or other power source, fluidly connected to a hydraulic reservoir 162, or other storage, and one or more hydraulic valves 164, 166, or other flow control devices. The hydraulic pump 160 can be a bi-directional variable displacement pump. The pump 160 can have an operation mode, providing fluid to the hydraulic system, or a neutral mode. The valves 164, 166 can be two-position, three-way directional control valves. The valves 164, 166 can each include a transducer or solenoid 165, 167 for actuating the valve. The input 170 of the hydraulic pump 160 can be fluidly connected to the hydraulic reservoir 162.

A first output 172 of the pump 160 can be fluidly connected to a first hydraulic valve 164 and the second output 174 can be fluidly connected to a second hydraulic valve 166. The first valve 164 can be fluidly connected to the reservoir 162 and a first port 176 of the connecting link 144. The second valve 166 can be fluidly connected to the reservoir 162 and a second port 178 of the connecting link 144. When the first valve 164 is in a first position, or operation position, the pump 160 is fluidly connected to first port 176 of the connecting link 144. When the first valve 164 is in a second position, or dump position, the first port 176 of the connecting link 144 is fluidly connected to the reservoir 162. When the second valve 166 is in a first position, or operation position, the pump 160 is fluidly connected to the second port 178 of the connecting link 144. When the second valve 166 is in a second position, or dump position, the second port 178 of the connecting link 144 is fluidly connected to the reservoir 162. In this embodiment, the crank arm 142 and the plunger 146 are coupled when the first and second valves 164, 166 are in their respective operation positions and the pump 160 is in the operation mode alternatively providing fluid to the first and second ports 176, 178 of the connecting link 144 via the first and second valves 164, 166. In addition, the crank arm 142 and the plunger 146 are decoupled when the first and second valves 164, 166 are in their respective dump positions and the pump 160 is in the neutral mode.

To retract the connecting link 144, and the connected plunger 146, the pump 160 provides fluid to the first port 176 via the first valve 164, in its operation position, and the second valve 166 can either be in the operation position or the dump position. The controller 180 can determine whether to retract the connecting link 144 and the speed of the retraction by controlling the quantity of fluid provided to the first port 176 through the first valve 164. To extend the connecting link 144, and the connected plunger 146, the pump 160 provides fluid to the second port 178 via the second valve 166, in its operation position, and the first valve 164 can either be in the operation position or the dump position. The controller 180 can determine whether to extend the connecting link 144 and the speed of the extension by controlling the quantity of fluid provided to the second port 178 through the second valve 166. Accordingly, to vary the speed of the retraction or extension of the plunger 146, the pump 160 varies the amount of fluid provided to first or second ports 176, 178 of the connecting link 144 via the first and second valves 164, 166 respectively.

With continued reference to FIG. 17, the baler 100 may include an electronic control unit 180, or controller, having one or more microprocessor-based electronic control units or controllers, which perform calculations and comparisons and execute instructions. The controller 180 may include a processor, a core, volatile and non-volatile memory, digital and analog inputs, and digital and analog outputs. The controller 180 may connect to and communicate with various input and output devices including, but not limited to, switches, relays, solenoids, actuators, light emitting diodes (LED's), liquid crystal displays (LCD's) and other types of displays, radio frequency devices (RFD's), sensors, and other controllers. The controller 180 may receive communication or signals, via electrically or any suitable electromagnetic communication, from one or more devices, determine an appropriate response or action, and send communication or signals to one or more devices. The controller 180 can be a programmable logic controller, also known as a PLC or programmable controller.

The controller 180 may connect to a baler 100 electronic control system through a data bus, such as a CAN bus, or the controller 180 can be a part of the baler 100 electronic control system. The controller 180 may be in communication with one or more devices including, but not limited to: the input shaft sensor 109 to receive information about the input shaft 108; the trip sensor 134 to receive information about the trip plate 132; the pre-compression chamber sensor 136 to receive information about the pre-compression chamber 120; the crank arm sensor 143 to receive information about the crank arm 142; the plunger sensor 147 to receive information about the plunger 146; the binding sensor 151 to receive information about the binding system 150 and/or binding operation; the measurement sensor 157 to receive information about the measuring device 156; the pump 150 and/or pump controller 161 to provide commands or instructions and/or receive information about direction and flow; valves 164, 166 and/or solenoids 165, 167 to provide commands or instructions and/or receive information about position and actuation; and a display 190 to receive commands or instructions and provide feedback. The controller 180 may receive communication from and provide communications, controls, or instructions to any of these devices.

FIG. 18 illustrates a method of operating a variable speed plunger 146 for a baler 100, which may be implemented in one or more of the embodiments described herein and depicted in the various FIGURES. At step 200, the method starts.

At step 202, the baler 100 is in the operation mode and the plunger 146 is extending and retracting into and out of the compression chamber 120 as the crank arm 142 rotates, such that a full revolution of the crank arm 142 fully extends and retracts the plunger 146 into and out of the compression chamber 120 in a proportional manner. Any movement of the crank arm 142 along the axis Z translates to a proportional movement of the plunger 142 along the axis Z. The crank arm 142 and plunger 146 can be considered synchronized. The controller 180 can varying the length of the crank arm 142 or connecting link 144 by controlling the pump 160 to alternately supply fluid to ports 176, 178 through valves 164, 166.

At step 204, an event phase is activated by a position of the crank arm 142, connecting link 144, or plunger 146, or an operation of the baler 100, such as the binding operation for example. The controller 180 can determine the activation of the event phase by communication with any of the sensors or other devices associated with the baler 100. The controller 180 may determine the commencement of the binding operation, or the activation of the binding system 150, based upon communication with sensor 151 or sensor 157.

At step 206, the controller 180 can change the speed of the plunger 146 at a different or disproportional rate than caused by the rotation of the crank arm 142 by varying or changing the length of the crank arm 142, the connecting link 144, or both. For example, the plunger 146 may increase or decrease speed at a faster rate than caused by the rotation of the crank arm 142. The displacement of the plunger 146 along the axis Z can be less than or greater than the displacement of the pivotal connection between the crank arm 142 and the connecting link 144 along the axis Z.

At step 208, the event phase completes based upon a position of the crank arm 142, connecting link 144, or plunger 146, or the completion of an operation of the baler 100, such as the binding operation for example. The controller 180 can determine the completion of the event phase by communication with any of the sensors or other devices associated with the baler 100. The controller 180 may determine the completion of the binding operation, or the deactivation of the binding system 150, based upon communication with sensor 151 or sensor 157.

At step 210, the controller 180 again changes the speed of the plunger 146 at a different or disproportional rate than caused by the rotation of the crank arm 142 to synchronize with the crank arm 142. If the controller 180 decreased the speed of the plunger 146 in relation to the crank arm 142 in step 206, then the controller 180 would increase the speed of the plunger in relation to the crank arm 142 in step 210, so that the plunger 146 would be synchronized and in the same position in relation to the crank arm 142 as the plunger 146 would have been without the change in speeds. If the plunger 146 increased speed in relation to the crank arm 142 in step 206, then the plunger would decrease speed in relation to the crank arm 142 in step 210, so that the plunger 146 would be synchronized and in the same position in relation to the crank arm 142 as the plunger 146 would have been without the change in speeds.

At step 212, the operation of the variable speed plunger 146 has occurred, according to one embodiment. In other embodiments, one or more of these steps or operations may be omitted, repeated, or re-ordered and still achieve the desired results.

FIG. 19 illustrates a method of operating a variable speed plunger 146 for a baler 100, which may be implemented in one or more of the embodiments described herein and depicted in the various FIGURES. At step 300, the method starts.

At step 302, the operational state or mode of the baler 100 is determined. A controller 180 may perform this determination by communicating with sensor 109, which can detect the speed of the input shaft 108, or sensor 143, which can detect the speed of the crank arm 142. If the baler 100 is not in an operation mode, then the method returns to step 300. If the baler 100 is in an operation mode, then the method continues with step 304.

At step 304, the plunger 146 is extending and retracting into and out of the compression chamber 120 as the crank arm 142 rotates, such that a full revolution of the crank arm 142 fully extends and retracts the plunger 146 into and out of the compression chamber 120 in a proportional manner. Any movement of the crank arm 142 along the axis Z translates to a proportional movement of the plunger 142 along the axis Z. When the crank arm 142 is rotating towards the extended position, the plunger 146 extends, and when the crank arm 142 is rotating towards the retracted position, the plunger 146 retracts. Accordingly, the crank arm 142 and plunger 146 can be considered synchronized in an active or run mode.

At step 306, the commencement of an event is determined. The controller 180 may determine whether the binding system 150 has been activated and the binding operation has commenced. If the event has not commenced, then the method returns to step 304. If the event has commenced, then the method continues to step 308.

At step 308, the position of the plunger 146 is determined. For example, the controller 180 can determine whether the plunger 146 is in the retracted, extended, or various intermediate positions. If the plunger 146 is not in the required position, for example at or near the extended position for the binding operation, then the method repeats step 308. If the plunger 146 is in the required position, then the method continues with step 310.

At step 310, the rate of displacement or speed of the plunger 146 along the axis Z is changed in relation to the rate of displacement or speed of the crank arm 142 along the axis Z. The controller 180 may control or direct the pump 160 to provide more or less fluid the valves 164, 166 to lengthen or shorten one of the crank arm 142 or the connecting link 144, which changes the speed of the plunger 146. For example, when the event is the binding operation, the variation in length of either the crank arm 142 or the connecting link 144 causes the plunger 146 to decrease speed near the extended position at a faster rate than if the crank arm 142 and the connecting link 144 were fixed lengths. The plunger 146 may reach the extended position at a slower speed and stay at the extended position for a longer period of time than if the crank arm 142 and the connecting link 144 were fixed lengths. The pump 160 can provide less fluid to valve 166 to decrease the speed the connecting link 144 was lengthening, which causes the plunger 146 to decrease speed at a different or disproportional rate to the crank arm 142; or the pump 160 can provide fluid to valve 164 to shorten the connecting link 144, which also causes the plunger 146 to decrease speed at a different or disproportional rate to the crank arm 142. The plunger 146 then remains at the extended position as the crank arm 142 begins to rotate away from the extended position. The variation in length of either the crank arm 142 or the connecting link 144 causes the plunger 146 to remain in the extended position. In this example, either the crank arm 142 or the connecting link 144 lengthens to maintain the plunger 146 in the extended position.

At step 312, the completion of an event is determined. The controller 180 may determine whether the binding system 150 has been deactivated because the binding operation has completed. If the event has not completed, then the method returns to step 310. If the event has completed, then the method continues to step 314.

At step 314, the rate of displacement or speed of the plunger 146 along the axis Z is again changed in relation to the rate of displacement or speed of the crank arm 142 along the axis Z. For example, when the completed event was the binding operation, the shortening in length of either the crank arm 142 or the connecting link 144 causes the plunger 146 to increase speed from the extended position towards the retraced position at a faster rate than if the crank arm 142 and the connecting link 144 were fixed lengths. The plunger 146 may retract from the extended position and reach the retracted position in a shorter period of time than if the crank arm 142 and the connecting link 144 were fixed lengths. The pump 160 can provide fluid to valve 164 to shorten the connecting link 144, which also causes the plunger 146 to increase speed at a different or disproportional rate to the crank arm 142. The plunger 146 can reach the retracted position at the same time the crank arm 142 reaches its initial or retracted position, as shown for example in FIG. 15A.

At step 316, the position of the crank arm 142 and plunger 146 is determined. The controller 180 may determine whether both the plunger 146 and the crank arm 142 are in their respective retracted positions. If they are not, then the method repeats step 316. If they are, then the method continues with step 318.

At step 318, the plunger 146 is again synchronized with the crank arm 142 in an active or run mode. The method can either return to step 302 or end.

After step 318, the activation of the variable speed plunger 146 has occurred, according to one embodiment. In other embodiments, one or more of these steps or operations may be omitted, repeated, or re-ordered and still achieve the desired results.

Without in any way limiting the scope, interpretation, or application of the claims appearing below, a technical effect of one or more of the example embodiments disclosed herein is controlling the movement of the plunger independently of the movement of the crank arm. Another technical effect of one or more of the example embodiments disclosed herein is the ability to perform slower compression rates of the crop material via the plunger within the compression chamber. Another technical effect of one or more of the example embodiments disclosed herein is the ability to maintain the plunger in the compressed position for a longer period of time during a harvesting machine operation, for example during the binding operation.

The terminology used herein is for the purpose of describing particular embodiments or implementations and is not intended to be limiting of the disclosure. As used herein, the singular forms “a”, “an” and “the” are intended to include the plural forms as well, unless the context clearly indicates otherwise. It will be further understood that the any use of the terms “has,” “have,” “having,” “include,” “includes,” “including,” “comprise,” “comprises,” “comprising,” or the like, in this specification, identifies the presence of stated features, integers, steps, operations, elements, and/or components, but does not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, and/or groups thereof.

The references “A” and “B” used with reference numerals herein are merely for clarification when describing multiple implementations of an apparatus.

One or more of the steps or operations in any of the methods, processes, or systems discussed herein may be omitted, repeated, or re-ordered and are within the scope of the present disclosure.

While the above describes example embodiments of the present disclosure, these descriptions should not be viewed in a restrictive or limiting sense. Rather, there are several variations and modifications which may be made without departing from the scope of the appended claims. 

What is claimed is:
 1. An agricultural harvesting machine for baling crop material, the agricultural harvesting machine comprising: a crank arm connected to a rotational power source for rotational movement; a plunger moveable within a compression chamber in a reciprocating motion along a z-axis between an extended position and a retracted position; a connecting link interconnecting the crank arm and the plunger for moving the plunger in the reciprocating motion along the z-axis in response to the rotational movement of the crank arm; wherein at least one of the crank arm and the connecting link is controllable to exhibit a variable length; a binding system operable to bind compressed crop material within the compression chamber into a bale; a crank sensor operable to sense data related to at least one of a rotational speed of the crank arm or a position of the crank arm; a plunger sensor operable to sense data related to at least one of a position of the plunger, a direction of the plunger, or a speed of the plunger; a controller in communication with the crank sensor and the plunger sensor and operable to control the variable length of the at least one of the crank arm and the connecting link based on data received from the crank sensor and the plunger sensor, wherein the controller is operable to: operate the plunger in an operation mode when the binding system is not activated, wherein the operation mode operates the crank arm and the connecting link in a synchronized state such that movement of the crank arm along the z-axis simultaneously moves the plunger a corresponding distance along the z-axis, and a speed of the crank arm relative to the z-axis is the same as a speed of the plunger relative to the z-axis; change the variable length of the at least one of the crank arm and the connecting link upon activation of the binding system such that the plunger remains substantially stationary in the extended position while the crank arm continues to rotate to maintain compression on the compressed crop material in the compression chamber while the binding system binds the compressed crop material into the bale; change the variable length of the at least one of the crank arm and the connecting link upon deactivation of the binding system such that the crank arm and the connecting link are returned to the synchronized state in which movement of the crank arm along the z-axis simultaneously moves the plunger a corresponding distance along the z-axis, and the speed of the crank arm relative to the z-axis is the same as the speed of the plunger relative to the z-axis; and maintain operation of the plunger in the operating mode with the crank arm and the connecting link in the synchronized state until the binding system is activated for a subsequent binding phase event.
 2. The agricultural harvesting machine set forth in claim 1, further comprising a measuring device operable to measure a length of the compressed crop material within the compression chamber and communicate the measured length to the controller.
 3. The agricultural harvesting machine set forth in claim 2, wherein the controller is operable to identify the activation and the deactivation of the binding system using the measured length of the compressed crop material in the compression chamber from the measuring device.
 4. The agricultural harvesting machine set forth in claim 1, further comprising a binding sensor operable to sense when the binding system is activated.
 5. The agricultural harvesting machine set forth in claim 4, wherein the controller is operable to identify the activation and the deactivation of the binding system using the sensed data from the binding sensor related to the activation of the binding system. 